DE102006014576A1 - Computer housing, has hard disk cage, which is rotatably arranged in computer housing using pivot bearing, and lock and/or brake unit, which hold hard disk cage in position using holding force - Google Patents

Abstract

The housing has a hard disk cage, which is rotatably arranged in the computer housing using a pivot bearing (20). A lock (22) and/or a brake unit (23) hold the hard disk cage in a position using a holding force. The lock is released through an effect of torque, which exceeds a certain value in a rotational direction, where the certain value of the torque is adjustable. A bearing support is fixed to the housing using screws, clamps, adhesives and welding.

Description

The The invention relates to a computer housing with a pivotable hard drive cage, wherein the hard drive cage by means of an upper pivot bearing and a lower pivot bearing in Computer housing swiveling is arranged.

swiveling HDD cages serve for holding hard disks and are arranged pivotally, so that the hard disks are easily accessible for assembly and disassembly. Also for maintenance purposes, the hard disks are by means of the swiveling Hard drive cage much easier to access as in housings without swiveling hard drive cage. hard drives are computer components containing a high proportion of electromechanical Have subcomponents. For example, disks include disk-shaped magnetic media that rotate at high speed while a read head with a very small distance to the magnetic disk the Read out data. Due to the high precision which the mechanical Components of a hard disk, and because of the low Distances, which have the subcomponents to each other is any vibration or shock load of hard drives a potential risk to damage the hard disks.

It is therefore the object of the invention to provide a hard drive cage, the re the shock load of recorded hard disks is improved.

These Task is through the measures of Patent claim 1 solved and with the measures the subordinate claims 2 to 16 developed in an advantageous manner.

The Invention includes the recognition that a significant shock load then exists when the hard drive cage during the assembly of a computer accidentally coincides with the built-in hard drive in the hard drive cage. A Improvement of a hard disk cage in terms of shock loads is according to the teaching of the claim 1 achieved in that the significant shock load in the Assembly is prevented. This is in the pivot bearing of the hard drive cage a Lock or a brake unit is provided which the HDD cage in one holds first position by means of a holding force. Thus, the hard drive cage can not accidentally fall, an uncontrollable shock load in the Hard drive cage arranged hard disks is thus prevented.

In the embodiment as a barrier, a mechanical element is provided, which by means of a positive Connect the hard drive cage holds in the first position. This is after a release the lock the hard drive cage freely swiveling. Because the release deliberately done by an installer during assembly or maintenance, the fitter is then able to continue the slewing process to do so and finish that no shock on built-in hard drives acts. An advantage of the design as a lock is that regardless of the number of built-in hard drives no further adjustment at the lock is required. The lock holds, due to the positive engagement the connection, even the higher one Torques at a higher Number of installed hard disks stood.

A advantageous embodiment provides that by the action of a torque in the pivoting direction the lock with which the HDD cage is held, is released. In this case, by the action of the torque, the positive connection solved, the hard drive cage is thus pivotable.

In the embodiment as a brake unit, an element is provided, which by frictional force the HDD cage frictionally in holds the first position. To the hard drive cage To pivot is first to overcome by means of torque friction. Is the stiction overcome, is the hard drive cage rotatable. Turns the hard drive cage, is to continue the rotation to overcome a sliding friction, the sliding friction is less than the static friction. This is also true while the pivoting action to overcome the frictional force of the brake unit. An advantage of this design is that accidental Zufallen excluded in any case, since the braking device in principle the hard drive cage can hold in any position of the pivoting process.

A alternative embodiment is the brake unit with the lock too combine, with the advantages of the two individual systems add up. Consequently is a mutually supportive Effect achievable.

A advantageous embodiment provides that the torque which is used to initiate the rotation is required, is adjustable. This can be an adaptation of the Hard drive cage to different configurations, where a different Number of hard drives is provided to be made.

It is advantageous, the lock or the brake unit on at least one to arrange the pivot bearing. This can be used in a component the pivot bearing, combine two functions. On the one hand, the swiveling Storage of the hard drive cage, and second, holding the hard drive cage in a first position.

Further Embodiments are described in the subordinate claims.

in the The invention is based on an embodiment with the aid of assistance from four figures closer explained. Show it:

The 1 a schematic representation of a computer housing with a pivotable hard drive cage,

the 2 a representation of a rotary bearing with adjustable torque in an exploded view,

the 3 a representation of the pivot bearing in a pre-assembled manner,

the 4 an example of an installation of the pivot bearing seen from a housing bottom of a computer,

the 5 the installation example from the 3 viewed from the hard drive cage,

the 6 an installation example of a computer case with swivel hard drive cage and the bottom side arranged adjustable pivot bearing.

In 1 is a computer case 18 with swiveling hard drive cage 17 shown in a partially schematic perspective view. The hard disk cage 17 is by means of an upper pivot bearing 20 and by means of a lower pivot bearing 21 pivotally mounted on the computer case. At the upper pivot bearing 20 a brake unit is arranged, which is a rotation of the hard disk cage 17 brakes, or holds the hard drive cage in an open position. Next is the embodiment of the lower pivot bearing 21 a lock 22 which also holds the HDD cage in an open position. brake unit 23 and lock 22 each one of them owns the HDD cage 17 to hold in the open position. Advantageous to the combination of brake unit 23 and lock 22 is a mutual redundancy of lock 22 and brake unit 23 , so even in case of failure of lock 22 or brake unit 23 the hard drive cage 17 still held. By a user, a force in the direction of a pivoting direction 19 exerted, then releases the lock by the action of torque 22 at the bottom pivot bearing 21 and the hard drive cage 17 can be panned. Next is by the action of the same torque on the brake unit 23 at the upper pivot bearing 20 the holding force of the brake unit 23 overcome.

At least one of the pivot bearings 20 or 21 is the minimum torque required for rotation adjustable. Due to the adjustability of the minimum torque is different for different configurations of the hard drive cage 17 the braking effect in the pivot bearing 20 or 21 customizable. Thus, a sudden Zufallen the hard drive cage 17 preventable. Furthermore, the torque is adjustable so that the hard drive cage 17 held in any position. This prevents the hard drive cage 17 alone due to its own weight. By action of the user or the assembler leaves the HDD cage 17 close nevertheless. Due to the adjustability of the torque is the required torque on the masses to be moved hard disk cage 17 and consequently the number of hard drives mounted in it and the size of the hard drive cage 17 adjustable.

2 shows a pivot bearing with a bearing block 1 , which bore a hole in the middle 2 having. The hole 2 itself has a star-shaped radially arranged on the circumference of the bore, four recesses 3 on. The hole 2 is on the bearing block 1 centered and the recess 3 repeats itself, leaving after a quarter of the perimeter of the hole 2 again a recess 3 is arranged. There are a total of four recesses 3 in the hole 2 intended. Into the hole 2 is a bearing bush 11 taken with the hard drive cage 17 is connectable. The bearing block 1 is a sheet steel part, which is trough-shaped. For fixing the bearing block 1 on a computer case 18 are mounting holes 4 intended. These mounting holes 4 are in interaction with screws 5 for fixing the bearing block 1 on the computer case 18 Set up the screws through the mounting holes 4 through in threaded holes 14 on the computer case 18 can be screwed.

The bearing block 1 has an upper and a lower side, with the upper side facing the hard drive cage 17 directed, and the bottom side of the hard drive cage 17 opposite side is. In the following, the two sides of the bearing are designated in one direction as viewed from the bearing. Thus, the upper side is referred to in the future as the inner side and the lower side referred to as the outer side. On the two sides of the bearing block 1 each is a locking disc 6 arranged. The locking discs are arranged concentrically to the center of the bore. The locking disc 6 has a catch 7 on which is in one of the recesses 3 locks. Thus, each of the two locking discs 6 opposite the bearing block 1 established. That is, an outer locking disc 6.1 is arranged on the outer side and an inner locking disc 6.2 is arranged on the inner side. These locking washers 6 lie directly on the external relationship wise inner side of the bearing block 1 on and are with the recess 3 which are in the hole 2 of the bearing block 1 is arranged, locked. The surface of the locking discs and the mechanical friction formed by the surface form against the rotational movement of the bearing bush 11 a braking moment.

The further construction of the bearing is through an inner plate spring 8th and an outer plate spring 9 educated. Another plate spring 10 is provided on the inner side of the bearing, which is used as a dial for adjusting the torque. Here are the two disc springs 8th and 10 each on the outer or on the inner locking disc 6.1 and 6.2 lying concentric to the center of the bore and comprise the bushing circular.

The disc springs 8th and 9 are therefore movable in itself, the locking discs 6 in themselves are immovable against the bearing block 1 , Due to the resilient design of the disc springs 8th and 9 is also the necessary torque adjustable, since the resilient property leads to a different support size and thus to different static friction between disc spring and locking disk.

With a bearing bush 11 which is an annular garland 12 has, the structure of the bearing is continued with adjustable torque. The bearing bush 11 is designed to fit in the hole 2 can be used of the position block. From the outside of the bearing is an adjusting screw 13 provided, which can be screwed into the bearing bush. Is the adjusting screw 13 screwed, it forms with its screw head an abutment against the outer spring washer 9 , By the tightening torque of the adjusting screw 13 is the minimum torque required for the rotation of the bearing infinitely adjustable. The screw head of the screw 13 and the ring-shaped wreath 12 be using the adjusting screw 13 pressed together. Thus, the intermediate components such as the locking discs ( 6 ) and the disc springs ( 8th . 9 . 10 ) pressed to each other. The resilient property of the disc springs 8th . 9 . 10 leads to a particularly fine and continuous adjustment of the minimum torque required to rotate the pivot bearing.

For setting particularly high minimum torques of 4 Nm to 6 Nm, the screw is provided in the exemplary embodiment 13 tighten to the stop and increase the contact pressure between disc springs and locking washers by means of another disc spring as a dial. This means that the screw is screwed in until the screw head and the rim 12 the bearing bush firmly against the intermediate disc springs.

To secure the screw 13 against unwanted self-loosening is the screw 13 self-locking executed. Preferably, a so-called permanent variant of self-assurance is to be used. That means the screw 13 not destructively solvable. This results in an insoluble screw connection.

In the embodiment, the screw 13 as M6 screw. The fixing screws 5 are designed as M3 screws. The warehouse is complete with all its parts in steel. Thus, minimum torques in a range of 4 Nm to 6 Nm are adjustable.

The bearing bush 11 points to the hard disk cage 17 turned side at least one threaded hole 14 on which for receiving fastening screws 15 is trained. This is the hard drive cage 17 firmly with the bearing bush 11 connectable. For fixing the hard disk cage 17 at the bearing bush 11 M4 threaded screws have proved to be advantageous.

The 3 shows the entire pivot bearing itself with all in 1 described components in a preassembled example. Here is the bearing block 1 of the pivot bearing with adjustable torque on the housing bottom of the computer case 18 arranged. A second pivot bearing is arranged in this embodiment so that the axis of rotation of the hard disk cage 17 in the vertical direction. The bearing block 1 is festgeleget for example by screws, clamps, gluing, welding or similar fastening methods on the computer case. Depending on the desired strength and the associated production costs as well as the mounting location of the bearing block 1 in the computer case 18 , one of the proposed attachment types is particularly suitable.

For mounting the bearing block 1 is on the case back of the computer case 18 a recess provided which the bearing block 1 from an outside of the computer case 18 receives. The indentation is advantageously provided with a bore that with the bore 2 of the bearing block 1 Aligns so that the bearing bush 11 in the assembled state passes through both holes. This embodiment facilitates the assembly of the bearing block 1 and thus also the mounting of the HDD cage 17 , In addition, this embodiment allows easy access to the adjusting screw 13 and thus also a slight adjustment of the torque from the outside of the housing of the computer case 18 ,

The 4 shows the pivot bearing in one playful application, in which the pivot bearing on a housing wall 16 a computer case 18 is attached from an outside. A hard drive cage 17 is shown in sections. The fastening of the hard disk cage 17 with the bearing bush 11 takes place via the mounting screws 15 , The bearing block 1 of the pivot bearing is with the mounting screws 5 attached to the bottom of the computer case.

The 5 shows the installation or application example of the 3 from a different perspective, viewed from the inside of the warehouse. The pivot bearing is from the outside of the housing wall 16 on the housing wall 16 set so that the inside of the pivot bearing is directed towards the inside of the housing. The hard disk cage 17 is with the fixing screws 15 at the bearing bush 11 established.

6 shows an embodiment of the computer case in a complete representation. Here is the housing wall 16 a bottom plate of the computer case, and the hard drive cage 17 is arranged pivotally. The axis of rotation of the hard disk cage runs in the vertical direction to the housing wall 16 , The housing wall 16 is in the illustrated embodiment, a bottom plate of the computer case. The bearing block 1 is from the outside to the housing wall 16 arranged. Thus, the adjustment screw 13 accessible from the outside. The swiveling hard drive cage 17 is with the fixing screw 15 on the pivot bearing, in particular on the bearing bush 11 attached. The bearing block is with the mounting screws 5 on the housing wall 16 attached.

In an assembly process where the computer case 18 lying with open HDD cage 17 an assembly worker is present, is achieved by means of the adjustable pivot bearing that accidental Zufallen the hard disk cage 17 is prevented. Are in the hard drive cage 17 For example, two hard disks installed, is to be expected with a torque at the pivot bearing of 4 Nm, which is slowed down by the adjustable pivot bearing. For four hard drives is already expected to about 6 Nm. The execution of the pivot bearing in steel allows the management of such torques.

1

bearing block

2

drilling

3

recess

4

mounting hole

5

fixing screw

6

Locking disc; outer locking disc ( 6.1 ) inner locking disc ( 6.2 )

7

locking lug

8th

inner Belleville spring

9

outer plate spring

10

Further Disc spring, shim

11

bearing bush

12

Wreath, abutment

13

adjustment

14

threaded hole

15

fixing screw

16

housing

17

Hard drive cage

18

computer case

19

pan direction

20

upper pivot bearing

21

lower pivot bearing

22

barrier

23

brake unit

Claims (16)

Computer case with pivoting hard drive cage, wherein the hard drive cage by means of at least one pivot bearing ( 20 . 21 ) is pivotally mounted in the computer housing, characterized in that a lock ( 22 ) and / or a brake unit ( 23 ) is provided, which the hard drive cage ( 17 ) holds in a first position by means of a holding force. Computer housing according to claim 1, characterized in that by the action of a torque, which exceeds a certain value, in the pivoting direction ( 19 ) the barrier ( 22 ) is solved. Computer housing according to claim 1, characterized in that by the action of a torque, which exceeds a certain value, in the pivoting direction ( 19 ) the holding force of the brake unit ( 23 ) is overcome. computer case according to one of the claims 2 or 3, characterized in that the specific value of the torque is adjustable. Computer housing according to one of the preceding claims, characterized in that the barrier ( 22 ) or the brake unit ( 23 ) on at least one of the pivot bearings ( 20 / 21 ) is arranged. Computer housing according to claim 5, characterized in that a bearing block ( 1 ) is provided with a bore ( 2 ), which at least one radially arranged recess ( 3 ), wherein in the bore ( 2 ) a bearing bush ( 11 ) is recorded. Computer housing according to claim 6, characterized in that the bearing block ( 1 ) into special is determined by screws, clamps, gluing or welding on the computer case. Computer housing according to one of the claims 6 to 7, characterized in that - an outer locking disc ( 6.1 ) and - an inner locking disc ( 6.2 ) are provided, which by means of a detent ( 7 ) from different sides of the bearing block ( 1 ) in the at least one recess ( 3 ) of the bore ( 2 ) and the bearing bush ( 11 ), so that the locking discs ( 6.1 and 6.2 ) on the bearing block ( 1 ). Computer housing according to one of the claims 6 to 8, characterized in that an inner plate spring ( 8th ) and an outer plate spring ( 9 ) are provided, which on the outer locking disc ( 6.1 ) or on the inner locking disc ( 6.2 ) and the bearing bush ( 11 ). Computer housing according to one of the claims 6 to 9, characterized in that the bearing bush ( 11 ) an annular ring ( 12 ), which as an abutment on the inner plate spring ( 8th ) rests. Computer housing according to one of the claims 6 to 10, characterized in that a further plate spring ( 9 ) is provided, which between the inner plate spring ( 8th ) and the wreath ( 12 ) is arranged. Computer housing according to one of the claims 6 to 11, characterized in that an adjusting screw ( 13 ) is provided with a screw head, which in the bearing bush ( 11 ) can be screwed, wherein the screw head an abutment against the outer plate spring ( 9 ). Computer housing according to one of the claims 6 to 12, characterized in that the bearing block ( 1 ) on a housing wall ( 16 ) of the computer housing is arranged. Computer housing according to claim 13, characterized in that the housing wall ( 16 ) is a housing bottom of the computer case. Computer housing according to claim 13 or 14, characterized in that on the housing wall ( 16 ) a recess is provided with a bore in which the bearing block ( 1 ) is fixed to the outside of the housing and wherein the bore to the bore ( 2 ) of the bearing block is arranged concentrically. Computer housing according to one of the claims 6 to 15, characterized in that on the bearing bush ( 11 ) Threaded holes ( 14 ) are provided, which are arranged, fastening means ( 15 ) for fixing the hard disk cage ( 17 ) on the bearing bush ( 11 ).